Sample selector

ABSTRACT

An apparatus includes a frame configured to hold sample holders in an array, a longitudinal axis of the sample holder extending outward of an array plane; a drive section connected to the frame; at least one transfer arm rotatably connected to the drive section so that each transfer arm rotates about a rotation axis oriented substantially parallel with the longitudinal axis and includes a sample holder gripper; and at least one push member movably connected to the drive section and being distinct from the sample holder gripper and configured for linear movement along the longitudinal axis, the at least one push member being configured so that engagement with at least a bottom or top surface of the sample holder effects longitudinal translation of the sample holder for one or more of capture and release of the sample holder by the respective transfer arm in the longitudinal direction.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a division of U.S. patent application Ser. No.14/229,077 filed on Mar. 28, 2014 (now U.S. Pat. No. 9,630,775), thedisclosure of which is incorporated by reference herein in its entirety.

BACKGROUND

1. Field

The exemplary embodiments generally relate to sample picking mechanismsand, more particularly, to sample picking mechanisms for use withinstorage and retrieval systems used to store and retrieve samples.

2. Brief Description of Related Developments

Storage of samples, such as biological or chemical samples, may bestored at or below freezing temperatures. Generally the samples arestored at ultra-low temperatures ranging, for example, between about−50° C. to about −90° C. or at cryogenic temperatures ranging, forexample, between about −140° C. to about −196° C. As used herein theterm “ultra-low temperature” shall mean temperatures below −50° C. andabove temperatures generally considered to be cryogenic.

Generally a mechanical robot is used to place and retrieve samples fromthe ultra-low temperature sample storage environment. However, theultra-low temperature environment may be too cold for reliable operationof conventional sample picking mechanisms.

It would be advantageous to have a sample picking mechanism that isoperable in ultra-low temperature environments where the drive(s) of thesample picking mechanism is (are) isolated from the ultra-lowtemperature environments.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing aspects and other features of the disclosed embodiment areexplained in the following description, taken in connection with theaccompanying drawings, wherein:

FIG. 1A is a schematic illustration of a sample storage facility inaccordance with aspects of the disclosed embodiment;

FIG. 1B is a schematic illustration of a sample storage facility inaccordance with aspects of the disclosed embodiment;

FIG. 1C is a schematic illustration of a sample selector module(s) inaccordance with aspects of the disclosed embodiment;

FIG. 1D is a schematic illustration of a sample selector module inaccordance with aspects of the disclosed embodiment;

FIGS. 2A and 2B are schematic perspective illustrations of a portion ofa sample selector in accordance with aspects of the disclosedembodiment;

FIG. 2C is a schematic perspective illustration of the sample selectorof FIGS. 2A and 2B in accordance with aspects of the disclosedembodiment;

FIG. 2D is schematic perspective illustration of a portion of the sampleselector of FIGS. 2A and 2B in accordance with aspects of the disclosedembodiment;

FIG. 3A is a schematic perspective illustration of a portion of thesample selector of FIGS. 2A through 2D in accordance with aspects of thedisclosed embodiment;

FIG. 3B is a schematic illustration of a portion of a sample tray inaccordance with aspects of the disclosed embodiment;

FIGS. 4, 4A, 4B, 4C, 4D and 4E are schematic illustrations of portionsof the sample selector of FIGS. 2A through 2D in accordance with aspectsof the disclosed embodiment;

FIGS. 5A and 5B are schematic illustrations of a portion of the sampleselector of FIGS. 2A through 2D in accordance with aspects of thedisclosed embodiment;

FIGS. 6A and 6B are schematic illustrations of a portion of the sampleselector of FIGS. 2A through 2D in accordance with aspects of thedisclosed embodiment;

FIGS. 7A and 7B are schematic illustrations of a portion of the sampleselector of FIGS. 2A through 2D in accordance with aspects of thedisclosed embodiment;

FIGS. 8A and 8B are schematic illustrations of a portion of the sampleselector of FIGS. 2A through 2D in accordance with aspects of thedisclosed embodiment;

FIG. 9 is a flow diagram in accordance with aspects of the disclosedembodiment; and

FIGS. 10A, 10B, 10C and 10D are schematic illustrations of a portion ofthe sample selector of FIGS. 2A through 2D in accordance with aspects ofthe disclosed embodiment.

DETAILED DESCRIPTION

FIG. 1A illustrates a sample storage facility or cold store 100 inaccordance with aspects of the disclosed embodiment. Although theaspects of the disclosed embodiment will be described with reference tothe drawings, it should be understood that the aspects of the disclosedembodiment can be embodied in many forms. In addition, any suitablesize, shape or type of elements or materials could be used.

The sample storage facility 100 may include any suitable number ofenvironmental zones or areas that may be isolated from one another. Forexample, the sample storage facility 100 may include one or moreultra-low temperature storage zones 110A, 110B, a transport zone 145 anda climate controlled antechamber 150. In other aspects the samplestorage facility 100 may have any suitable number and type ofzones/areas in which samples are stored and/or transported and which maybe accessed by storage facility personnel.

In one aspect the transport zone 145 may include an input/output, module130, a transport shuttle 112 and one or more sample selector modules 200where the sample selector modules are disposed at least partly withinthe transport zone 145 as will be described below. The input/outputmodule 130 may allow transfer of samples and/or sample trays to and fromthe sample storage facility 100 while maintaining a predeterminedtemperature within the transport zone 145. The sample selector modules200, which will be described in greater detail below, may providesorting capability for moving samples/sample holders within or betweenstandard density (SD) and/or high density (HD) sample racks/trays.

The transport zone 145 may be maintained at any suitable lowtemperature, such as about −20° C., in which a transport shuttle 112and/or other automation may operate to transfer sample trays between theultra-low temperature storage zones 110A, 110B, the sample selectormodules 200 and the input/output module 130. The transport shuttle 112may interface with a tile wall 115 where each tile is arranged tocreate, for example, a robotically friendly insulating closure of theultra-low temperature zones 110A, 110B for removing sample trays fromthe ultra-low temperature zones 110A, 110B in any suitable manner. Thetransport shuttle 112 may be configured to transport the sample traysbetween the ultra-low temperature zones 110A, 110B and any othercomponents of the sample storage facility as described herein, which mayinclude but is not limited to transport of sample trays to and from thesample selector modules 200.

In one aspect the climate controlled antechamber 150 may include doors150D1, 150D2 for providing personnel access to the at least thetransport zone 145 and/or to the sample selector modules 200, at leastpart of which may be disposed within the climate controlled antechamber150 (e.g. the sample selector modules 200 may be mounted through a wallseparating/isolating the antechamber 150 from the transport zone 145. Asmay be realized, the climate controlled antechamber 150 may bemaintained at any suitable temperature allowing for human entry into theantechamber 150.

The sample storage facility 100 may include any suitable refrigerationsystem(s) 125 and/or dehumidification system(s) 120 for maintainingrespective predetermined temperatures within the different zones of thesample storage facility 100. In one aspect the transport zone 145,transport shuttle 112, tile wall 115, ultra-low temperature storagezones 110A, 110B, transport zone 145 and input/output modules of thesample storage facility 100 may be substantially similar to thosedescribed in U.S. Pat. No. 7,635,246 issued on Dec. 22, 2009, U.S. Pat.No. 7,648,321 issued on Jan. 19, 2010, U.S. Pat. No. 7,793,842 issued onSep. 14, 2010, U.S. Pat. No. 8,252,232 issued on Aug. 28, 2012 and U.S.patent application Ser. No. 13/595,817 filed on Aug. 27, 2012 and Ser.No. 13/334,619 filed on Dec. 22, 2011, the disclosures of which areincorporated by reference herein in their entireties.

FIG. 1B illustrates a sample storage facility 100′ in accordance withaspects of the disclosed embodiment. The sample storage facility 100′may be substantially similar to sample storage facility 100 describedabove and include any suitable number of environmental zones or areas110A, 110B, 145 that may be isolated from one another. Here one or moresample selector modules 200 may be mounted through an exterior wall ofthe sample storage facility 100′ rather than through a wallseparating/isolating the antechamber 150 from the transport zone 145 orany other suitable zone of the sample storage facility 100.

FIG. 1C is a schematic illustration of sample selector modules 200. Asmay be realized, any suitable number of sample selector modules (two areshown in FIG. 1C) may be stacked one above the other as shown in FIGS.1B and 1C or disposed side by side as illustrated in FIG. 1A. Eachsample selector module 200 may be connected to or otherwise include anysuitable refrigeration system 200R configured to maintain at least aportion of an interior of the sample selector at a predeterminedultra-low temperature as will be described below. In one aspect eachsample selector module 200 may have a respective refrigeration system200R while in other aspects a common refrigeration system may beprovided for two or more sample selector modules 200 or the sampleselector module(s) may share a common refrigeration system with othercomponents (such as ultra-low temperature storage zones 110A, 110B) ofthe sample storage facility 100, 100′.

Referring also to FIG. 1D one or more sample selector modules 200 (and,in some instances, the respective refrigeration system 200R) may bemounted to, for example, the transport shuttle 112 so that the one ormore sample selectors 200 move as a unit with transport shuttle 112.Here the transport shuttle 112 may include a transfer arm 112Aconfigured to remove sample trays from the ultra-low temperature zones110A, 110B (or any other suitable location of the sample storagefacility 100, 100′) and place the sample trays within the one or moresample selector modules 200 disposed on the transport shuttle 112. Oneor more samples from the samples frays may be sorted and/or transferredto a different tray, such as between source and destination trays,within the ultra-low temperature environment of the sample selectormodule 200 allowing the source tray to be placed back into the ultra-lowtemperature zone 110A, 110B. As may be realized, in aspects where thesample storage zone is the same temperature in which the transportshuttle 112 operates the sample selector 200 may not have a temperaturecontrolled environment (e.g. such as the ultra-low temperatureenvironment) but may be open to the transport shuttle operatingenvironment.

Any suitable controller 170 may be connected to the sample storagefacility 100, 100′ in any suitable manner, such as through a wired orwireless connection. The controller 170 may be configured to control theoperation of the sample storage facility 100, 100′. For example, thecontroller 170 may include any suitable memory and processors and beconfigured to track which samples are inserted and/or removed from thesample storage facility 100 and a location of each sample within thesample storage facility 100. The controller 170 may also be configuredto control automation within the sample storage facility where theautomation includes, but is not limited to, the transport shuttle 112and sample selector modules 200 to transfer samples as described herein.

Referring now to FIGS. 2A, 2B, 2C and 2D each sample selector module 200includes a frame 210F, at least one transfer device or unit 201A, 201Bhaving a drive section 201 connected to the frame 210F and at least onetransfer arm portion 400A (see FIGS. 4 and 4A) rotatably connected tothe drive section 201. The frame 210F may include a cover portion 210Cand a base portion 210B or include any suitable number of panels/walls(or a unitary/one piece panel) that form/forms a housing 200H configuredto hold at least one isolated or sealed environment therein. The housing200H may include a longitudinal axis LON and a lateral axis LAT and maybe divided into isolated zones/areas. In one aspect the base portion210B includes lateral walls 210LTA, 210LTB, longitudinal walls 210LNA,210LNB, a bottom wall 210BW and an isolation member 263 disposedopposite to and spaced apart from the bottom wall 210BW (the term“bottom” is used herein for exemplary purposes only and in other aspectsany suitable spatial identifiers may be associated with the wall 210BW)so as to form an isolated climate controlled chamber or zone 223. In oneaspect the isolated climate controlled chamber 223 may be maintained atan ultra-low temperature, such as for example, about −80° C. or anyother suitable ultra-low temperature. In one aspect the isolated climatecontrolled chamber 223 may be actively cooled while in other aspects theisolated climate controlled chamber 223 may be cooled in any suitablemanner. One or more evaporators EVAP may be disposed within the isolatedclimate controlled chamber 223 and be configured to maintain, forexample, a uniform ultra-cold temperature distribution within theisolated climate controlled chamber 223. In one aspect the one or moreevaporators EVAP may be disposed on a surface of the isolation member263 forming an interior wall of the isolated climate controlled chamber223 (e.g. on a ceiling of the chamber). In other aspects the one or moreevaporators EVAP may be disposed at any suitable location within theisolated climate controlled chamber 223, such as for example, on asurface of the walls 210LTA, 210LTB, 210LNA, 210LNB, 210BW that form aninterior wall of the isolated climate controlled chamber 223. The one ormore evaporators EVAP may be flat plate evaporators or any othersuitable evaporator.

As may be realized, the isolation member 263 may also be disposedopposite to and spaced apart from a top wall 210TW (e.g. the isolationmember is disposed between the top and bottom walls 210TW, 210BW) so asto form a drive section chamber 224 that may be maintained at anysuitable predetermined temperature suitable for the operation of drivesection 201 components as described herein. In one aspect, the drivesection chamber 224 may be maintained at any suitable temperature above,for example, ultra-low temperatures such as a temperature of about −20°C.

At least one of the of the longitudinal walls 210LNA, 210LNB and thelateral walls 210LTA, 210LTB may include one or more input/outputopenings or apertures 260A, 260B, 260C through which sample trays 310TRpass for insertion to and removal from the isolated climate controlledzone 223. Each input/output opening 260A, 260B, 260C may be a sealableor otherwise closable opening that is sealed or otherwise closed by arespective sliding tile 261A, 261B, 261C. Suitable examples of slidingtile closures can be found in, for example, U.S. Pat. Nos. 7,635,246;7,648,321 and 7,793,842; and U.S. patent application Ser. Nos.13/595,817 and 13/334,619, previously incorporated by reference herein.In one aspect the tiles 261A, 261B, 261C may be foam bricks or blocksthat are arranged to create, for example, a robotically friendlyinsulating closure. In other aspects, the tiles 261A, 261B, 261C may beconstructed of any suitable material and may interface with any suitableautomation and/or personnel for opening and closing a respectiveinput/output opening 260A, 260B, 260C in any suitable manner. In oneaspect, the tiles 261A, 261B, 261C may be held in place (e.g. in aclosed position) by gravity or in any other suitable manner. Guide rails262R on each side of a respective tile may constrain the tiles againstlateral movement while allowing them to slide up and down freely in thedirection of arrow 299 for opening and closing a respective input/outputopening 260A, 260B, 260C. In one aspect, any suitable automated transfermechanism of the sample storage facility 100, such as transport shuttle112, may insert or remove a sample tray 310TR to or from the isolatedclimate controlled zone 223 through an input/output opening 260A, 260B,260C by aligning the automated transfer mechanism with the tile 261A,261B, 261C in front of the desired opening. Each tile 261A, 261B, 261Cmay be configured with one or more gripping members PH, such as a recessor protrusion, that allows the automated transfer mechanism to lift thetile 261A, 261B, 261C for opening the input/output opening 260A, 260B,260C in, for example, a manner substantially similar to that describedin U.S. Pat. Nos. 7,635,246; 7,648,321 and 7,793,842; and U.S. patentapplication Ser. Nos. 13/595,817 and 13/334,619, previously incorporatedby reference herein. In other aspects the sample selector module 200 mayinclude one or more drives coupled to each of the tiles 261A, 261B, 261Cfor moving the tiles in the direction of arrow 299 to open and close arespective input/output opening 260A, 260B, 260C.

As may be realized, each tile 261A, 261B, 261C may form any suitableseal with the respective wall 210LNA, 210LNB, 210LTA, 210LTB. In oneaspect the seal may be a selectively activated magnetic seal that may beactivated when the tiles 261A, 261B, 261C are in a closed position. Themagnetic seal may be deactivated to allow movement of the tiles 261A,261B, 261C in the direction of arrow 299 for opening and closing therespective input/output opening 260A, 260B, 260C. In other aspects themagnetic seal may be a passive seal where the robot, other automation ora user is able to overcome a sealing force provided by the passivemagnetic seal for moving the tiles 261A, 261B, 261C in the direction ofarrow 299 for opening and closing the respective input/output opening260A, 260B, 260C. For example, the magnetic seal may be provided by anysuitable magnet having, for example, high normal forces and lower shearforces such as neodymium magnets so that the respective tile 261A, 261B,261C is held or otherwise biased against the wall while being able tomove relative to the respective input/output opening 260A, 260B, 260Cfor opening and closing the respective input/output opening 260A, 260B,260C. It is noted that the tiles, such as tiles 261A, 261B, 261C, may bedisposed on any suitable enclosure 133 that is accessed by the transportshuttle 112 or any other suitable transport of the sample storagefacility 100, 100′. In one aspect the enclosure 133 may be an enclosurefor one or more of a sample picking module a bar code reader, an inputoutput module, a storage module or any other suitable device thatinterfaces with one or more sample containers.

Referring also to FIG. 3A, each of the input/output openings 260A, 260B,260C may be associated with a respective sample tray holder 300A, 300B,300C. Each sample tray holder 300A, 300B, 300C may include respectivesample tray supports 300R1, 300R2 that may be supported by the frame210F in any suitable manner. While a single level or plane of sampletray holders is illustrated in FIG. 3A, in other aspects there may bemultiple stacked levels or planes of sample tray holders within theisolated climate controlled zone 223 (as will be described below)between which sample containers may be transferred. The sample traysupports 300R1, 300R2 may be spaced from each other by any suitableamount so that a sample tray 310TR may be slid into or out of therespective sample tray holder 300A, 300B, 300C by a tray conveyor thatis external to the sample selector module 200 (e.g. the tray conveyor isone that is separate from the sample selector module 200 such as thetray shuttle 112). In one aspect, each sample tray holder 300A, 300B,300C may have a length suitable for holding a sample tray 310TR havingone or more standard density or high density sample racks (see the highdensity sample racks generally referred to as high density racks 370 inFIG. 3B and the standard density sample racks generally referred to asstandard density racks 570 in FIGS. 5A-7B which will be described ingreater detail below) disposed thereon such that, the sample racks arearranged end to end (e.g. referring to FIGS. 3B and 3C for exemplarypurposes only, a first end of a sample racks 370E1 substantially abutsagainst a second end 370E2 of another sample rack 370). In other aspectsthe sample tray 310TR may be configured to hold samples containerdirectly thereon (e.g. without a tray) such that the sample containerholding locations 310 are formed in the sample tray 310TR or areotherwise affixed thereto in a standard density or high densitycapacity. The sample trays 310TR (and/or the racks 370, 570 heldthereon) may be configured to hold sample containers of holder SC in anarray of sample containers, where the array has an array plane SCP. Thesample containers SC may be arranged in the sample trays 310TR (and/orthe racks 370, 570 held thereon) so that a longitudinal axis SCLA of thesample containers SC extends outward of the array plane. In one aspecteach sample tray holder 300A, 300B, 300C may include a retention unit300L1 and/or locating unit 300L2 for securely holding and locating thesample tray(s) 310TR within the sample tray holder(s) 300A, 300B, 300Cin a repeatable manner so as to place each sample holding location 310of the sample racks in a predetermined position relative to a coordinatesystem of the sample picker module 200.

Referring also to FIG. 1A, in one aspect, a sample tray 310TR may beinserted into the sample selector module 200 by positioning the sampletray on a tray support surface 112S of the transport shuttle 112. Thesample tray 310TR may be positioned by the tray shuttle 112 at a heightcorresponding to a predetermined input/output opening 260A, 260B, 260C.The transport shuttle 112 may slide a predetermined tile 261A, 261B,261C to open an associated input/output opening 260A, 260B, 260C in anysuitable manner, such as that described above. The transport shuttle mayslide the sample tray 310TR into the sample tray holder 300A, 300B, 300Cassociated with the predetermined input/output opening 260A, 260B, 260Cusing, for example, a transfer arm 112A of the transport shuttle 112. Inone aspect the sample tray may include any suitable gripping featurethat allows the transport shuttle 112 to grip the sample tray 300TR forsliding the sample tray to and from the sample tray holder 300A, 300B,300C. The transfer arm 112A may be removed from the sample selectormodule 200 and the tile may be moved to close or otherwise seal theinput/output opening 260A, 260B, 260C. Removal of the sample tray 300TRmay be performed in substantially the opposite manner to that describedabove.

Referring again to FIGS. 2C and 2D, another one of the longitudinalwalls 210LNA, 210LNB and/or the lateral walls 210LTA, 210LTB may includea user access door 250 configured to allow a user access to one or moreof the drive section chamber 224 and the isolated climate controlledchamber 223. Opening or removal of the door 250 may providesubstantially direct user access to the drive section chamber 224. Inone aspect any suitable barrier member 224B may be connected to theframe 210F to form, for example, a removable moisture barrier betweenthe drive section chamber 224 and the user environment. In one aspectthe barrier member 224B may be a translucent member allowing visualinspection of the drive section chamber 224 without removal of thebarrier member 224B. Opening or removal of the door 250 may also provideaccess to the isolated climate controlled chamber 223. In one aspectopening the user access door 250 may provide substantially direct accessto the isolated climate controlled chamber 223. In other aspects accessto the isolated climate controlled chamber 223 may be provided throughan ultra-cold temperature interface or thermal panel 223I. Theultra-cold temperature interface or thermal panel 223I may be coupled tothe frame 210F so as to substantially seal or otherwise isolate theisolated climate controlled chamber 223 from the user environment whenthe door 250 is opened or removed. The ultra-cold temperature interface223I may include one or more suitable sealable apertures 272 throughwhich gloves may be inserted. In one aspect any suitable covers 272C maybe provided for sealing the apertures 272 while in other aspects thegloves may be attached to the apertures to seal the apertures.

As may be realized, any suitable seals may be provided between therespective wall 210LNA, 210LNB, 210LTA, 210LTB and one or more of theuser access door 250, barrier member 224B and ultra-cold temperatureinterface 223I. For example, where the user access door 250 providesdirect access to one or more of the drive section chamber 224 andisolated climate controlled chamber 223, any suitable seals may beprovided between the door 250 and walls 210LNA, 210LNB, 210LTA, 210LTB(and isolation member 263) for sealing or otherwise isolating one ormore of the drive section chamber 224 and isolated climate controlledchamber 223 from each other and from an environment outside the sampleselector module 200. In other aspects, the barrier member 224B may forma seal with the walls 210LNA, 210LNB, 210LTA, 210LTB (and isolationmember 263) for sealing or otherwise isolating the drive section chamber224. As noted above, the ultra-cold temperature interface 223I may becoupled to the frame 210F so as to substantially seal or otherwiseisolate the isolated climate controlled chamber 223 from the userenvironment when the door 250 is open or removed. The seals between therespective wall 210LNA, 210LNB, 210LTA, 210LTB and one or more of theuser access door 250, barrier member 224B and ultra-cold temperatureinterface 223I may be magnetic seals similar to those described abovewith respect to tiles 261A, 261B, 261C or they may be any suitable sealsprovided individually or in conjunction with each other.

Referring now to FIGS. 3A, 4 and 4A, as noted above the sample transfermodule 200 includes one or more transfer devices 201A, 201B. Eachtransfer device 201A, 201B (described herein with respect to transferdevice 201A but it should be understood that transfer device 201B may beidentical to transfer device 201A) includes a respective drive portion202A of drive section 201 and a transfer arm portion 400A. The driveportion 202A may be disposed within the drive section chamber 224 andinclude one or more rotary drive motors 401, 402, 403 connected to aframe 400F of the drive portion 202A. In one aspect the drive portion202A may also include at least one linear drive motor 201L2 connected tothe frame 400F for moving at least a portion of the transfer arm portion400A in the direction of arrow 299.

In one aspect, the drive portion 202A may be coupled to the frame 210Fof the sample selector module 200 in any suitable manner. For example,the drive portion 202A may be mounted to a linear drive 201L1 of thedrive section 201 that is supported within the frame 210F so that a pathof travel of the linear drive 201L1 and movement of the transfer armportion 400A carried by the linear drive 201L1 is substantially in thedirection of arrow 298 (e.g. along a longitudinal axis of the sampletray 310TR or towards and away from the longitudinal walls 210LNA,210LNB) so that the transfer arm portion travels along a respectiveaisle formed between the sample fray holders 300A, 300B, 300C. In otheraspects the linear drive 201L1 may be a multi-axis linear driveproviding movement of the transfer arm portion 400A in the direction ofarrows 297, 298. The linear drive 201L1 may be any suitable linear drivesuch as a linear stepper motor, a belt and pulley system, a screw driveor any other suitable drive. In one aspect the drive portion 202A mayride along one or more linear rails 405A, 405B of the linear drive 201L1while in other aspects the drive portion 202A may be supported by thelinear drive 201L1 in any suitable manner. As may be realized, anysuitable encoders or position detectors 406 may be provided fordetermining, along with controller 170, a position of the transfer armportion 400A along a length of the linear drive 201L1 for positioningthe transfer arm portion 400A relative to the sample holding locations310 within the sample tray 310TR.

The transfer arm portion 400A may include a coaxial (e.g. concentricallycollocated) drive shaft assembly 460 having a common axis of rotation RX(which may be substantially parallel with the sample containerlongitudinal axis SCLA), a sample container holder 440, a top (e.g.upper) pusher member 430 and a bottom (e.g. lower) pusher member 420. Itis noted that the terms “top” and “bottom” make reference to an end orsurface of a sample container that a sample container engagement portion420A, 420B (described below) of the respective “pusher member” engages(e.g. the “top” surface SCT of the sample container SC includes anopening that is closed by a cap and the “bottom” surface SCB of thesample container includes a closed end of the sample container SCopposite the opening) and in other aspects any suitable spatialreferences/identifiers may be used. The coaxial drive shaft assembly 460and other components of the transfer arm portion 400A may be constructedof any suitable material such as, for example, a thermallynon-conductive material configured to isolate the samples held by thetransfer arm portion 400A from heat generated by the drive portion 201A,202A and to isolate the drive portion from the ultra-cold temperature inwhich the transfer arm portion 400A operates.

The coaxial drive shaft may be coupled to the respective drive portion202A in any suitable manner (such as described below) and extend throughthe isolation member 263 into the isolated climate controlled chamber223. In one aspect the isolated climate controlled chamber 223 mayinclude one or more narrow slots 263P (e.g. a value of longitudinallength of the slot is much less than a value of the lateral width of theslot) through which a respective coaxial drive shaft assembly 460extends. The narrow slots 263P may be decoupled from at least one degreeof freedom of a respective transfer device 201A, 201B in the array planeSCP. The narrow slot 263P may be sealed in any suitable manner such aswith a dynamic seal 263S that moves with the coaxial drive shaftassembly 460 as the coaxial drive shaft assembly 460 travels in thedirection of arrow 298 along a longitudinal length of the respectivenarrow slot 263P. As may be realized, the decoupling of the narrow slot263P from the at least one degree of freedom of the respective transferdevice 201A, 201B may allow for seal movement in only a singledirection, such as along a travel axis in the direction of arrow 298 ofa respective transfer arm portion. In other aspects the narrow slot 263Pmay not be sealed where the isolation of the isolated climate controlledchamber 223 may be achieved by air currents flowing from the isolatedclimate controlled chamber 223 into the drive section chamber 224 dueto, for example, a temperature differential between the two chambers,however the drive section chamber 224 may be maintained at apredetermined non-ultra-cold temperature in any suitable manner thataccounts for cooling of the drive section chamber 224 by the passage ofultra-cold air into the drive section chamber 224. As may be realized,the narrow slots 263P (whether sealed or not sealed) may provide forincreased thermal management, improved sample integrity and lower powerusage by limiting or otherwise eliminating communication between the twochambers 223, 224.

The sample container holder 440 may be coupled to an outer drive shaft440S of the coaxial drive shaft assembly so that the sample containerholder 440 and the outer drive shaft rotate as a unit about axis RX. Inone aspect the coaxial drive shaft assembly 460 may include an innershaft having shaft portions 460S, 420S that may be formed as a singleunit or coupled together in any suitable manner so as to rotate as asingle unit where the inner shaft is disposed at least partly within theouter drive shaft 440S. The top pusher member 430 may be mounted toshaft portion 430S while the bottom pusher member 420 is mounted toshaft portion 420S so as to be located on opposite sides along the axisRX of the sample container holder 440. As may be realized, the outerdrive shaft 440S may include an aperture through which the top pushermember 430 extends where the aperture may be configured to allowrelative movement between the top pusher member 430 and the samplecontainer holder 440. In one aspect each of the outer and inner driveshafts 440S, 430S, 420S may be coupled to a common rotary drive motor401 so that the shafts 440S, 430S, 420S and hence the sample containerholder 440, top pusher member 430 and bottom pusher member 420 rotate asa unit about the axis RX. The inner drive shaft formed by shaft portions430S, 420S may be linearly moveable within the outer drive shaft 440Sand be coupled to the at least one linear drive 201L2 for moving the topand bottom pusher members 430, 420 as a unit in the direction of arrow299 relative to the sample container holder 440. In one aspect of thedisclosed embodiment the coupling between each of the rotary drivemotor(s) 401, 402, 403 and the at least one linear drive motor 201L2with a respective shaft of the coaxial drive shaft assembly 460 may be asubstantially direct coupling (e.g. no intervening belts or chains). Forexample, as shown in FIG. 4, each drive motor may include a drive gearDG1 (or any other suitable drive coupling) coupled to an output shaft ofthe drive motor that directly engages a driven gear DG2 (or any othersuitable drive coupling) coupled substantially directly to a respectivedrive shaft without any intervening gears or other transmission members.In another aspect the motor rotor (e.g. moving portion of the motor) maybe formed in or otherwise attached to a respective drive shaft such thatthe drive shaft effectively forms the rotor of the motor. In still otheraspects of the disclosed embodiment any suitable transmission may beprovided between the motor and respective drive shaft(s) for driving thetransfer devices 201A, 201B as described herein.

As may be realized, the one or more rotary drive motor 401, 402, 403,the at least one linear drive motor 201L2 and the linear drive 201L1 mayconstitute a mixed Polar-Cartesian coordinate system that allowstransfer of sample containers between sample holding locations 310 of asingle sample rack 370, 570 or between different sample racks 370, 570located in one or more sample trays 310TR with as few as three drivemotors (e.g. as described above). In other aspects, more than threemotors may be used, as described below, for the transfer of samplecontainers between sample holding locations 310 of a single sample rack370, 570 or between different sample racks 370, 570 located in one ormore sample trays 310TR. As may be realized, polar coordinate mapping ofsample holding locations 310 may allow fast coordinated motion to thesample holding locations 310 on two sample trays 310TR by each transferdevice 201A, 201B. In still other aspects the drive portion 202A may bemounted to the frame 210F so as to be fixed with respect to linearmovement towards and away from the side walls 210LNA, 210LNB, 210LTA,210LTB of the sample transfer module 200 (e.g. linear drive 201L1 is notprovided) so that the transfer device 201A, 201B operates substantiallyin a pure Polar coordinate system.

In another aspect the shaft portion 430S may form a middle drive shaftand the shaft portion 420S may form an inner drive shaft where at leastthe inner drive shaft is independently rotatable relative to the outerdrive shaft 440S. For example, the outer drive shaft 440S and the shaftportion 430S (e.g. middle drive shaft) may be coupled to a common rotarydrive motor 401 so that the fop pusher member 430 and the samplecontainer holder 440 rotate as a unit about axis RX while shaft portion420S (e.g. inner drive shaft) is coupled to a separate rotary drivemotor 402 so that the bottom pusher member 420 independently rotatesabout axis RX. In still another aspect the shaft portion 430S (e.g.middle drive shaft) may be coupled to a separate rotary drive motor 403so that each of the top pusher member 430, sample container holder 440and bottom pusher member 420 are independently rotatable relative toeach other. In yet another aspect, where the shaft portion 430S and theshaft portion 420S respectively form middle and inner drive shafts, theshaft portion 430S may be coupled to one linear drive motor of the atleast one drive motor 201L2 while the shaft portion 420S may be coupledto another linear drive motor of the at least one drive motor 201L2 sothat each of the top pusher member 430 and the bottom pusher member 420are independently movable in the direction of arrow 299 relative to thesample container holder 440.

As may be realized the rotary drive motor(s) 401, 402, 403 and the atleast one linear drive motor 201L2 may include any suitable encoders orposition detectors for determining, along with controller 170, aposition of the transfer arm portion 400A along a length of the lineardrive 201L1 for positioning the transfer arm portion 400A relative tothe sample holding locations 310 within the sample tray 310TR. As mayalso be realized, the motor control adjustment of the stroke (e.g.amount of movement) of at least the top and bottom pusher members 430,420 in the direction of arrow 299 may allow for the picking and placingof sample containers having different heights H (FIG. 4C).

Referring now to FIG. 4A the sample container holder 440 may include agripper or sample container receiver 440A that is configured to hold oneor more sample container types (e.g. different shapes of samplecontainers). In one aspect the gripper 440A may be an interchangeablegripper that is removable from the sample container holder 440 andreplaceable with a different gripper 440A′ having a differentpredetermined characteristic than the gripper 440A. The differentpredetermined characteristics may include, for example, an ability tohold a different size/shape sample container, movable gripper actuators,a configuration for punching sample containers to/from a sample tray, aconfiguration for pushing sample containers to/from a sample tray, aconfiguration to both punch and push sample containers to/from a sampletray, etc., where the term “punch” refers to transfer of a sample tubepast a bottom surface of a sample tray and “push” refers to the transferof a sample tube past a top surface of a sample tray (for ease ofexplanation the terms “punch” and “push” are generally referred toherein as “push”). In one aspect the gripper 440A may include a basemember 440B that is coupled in any suitable manner to (so as to beinterchangeable with other grippers) or integrally formed with thesample container holder 440. The base member 440B may include anaperture that passes through the base member 440B so as to form a samplecontainer passage 440P through the base member 440B where the samplecontainer passage 440P includes an axis AX extending through the passageand substantially along which sample containers SC are held by thegripper 440A. One or more biasing members 440S, such as springs or otherresilient member, may be disposed at least partially within the samplecontainer passage 440P for biasing a sample container SC (FIG. 4C)against a surface of the sample container passage 440P to effect africtional engagement and retention of the sample container SC withinthe sample container passage 440P.

Referring now to FIGS. 4B and 4C, a gripper 440A″ is illustrated inaccordance with an aspect of the disclosed embodiment. The gripper 440A″may be substantially similar to gripper 440A however, the gripper 440A″may have at least one actuable or movable gripping member or finger470M. For example, the base member 440B″ may include a stationary finger470S that forms at least part of the sample container passage 440P. Inthis aspect the stationary finger 470S has a semicircular shape so as tosubstantially conform with a shape of the sample container SC but inother aspects the stationary finger 470S may have any suitable shape.The movable finger 470M may be pivotally mounted to the base member440B″ in any suitable manner so as to be pivotable about an axis ofrotation RX1. The movable finger 470M is illustrated as having asubstantially “L” shaped configuration for exemplary purposes and inother aspects the movable finger 470M may have any suitable shape. Themovable finger 470M may include a gripping portion 470MG and an actuatorportion 470MA where the gripping portion 470MG is positioned relative tothe base member 440B″ to be in an opposing arrangement with thestationary finger 470S so that as the movable finger 470M pivots aboutaxis RX1 the gripping portion 470MG moves towards the stationary finger470S for gripping the sample container SC and away from the stationaryfinger 470S for releasing the sample container SC. In one aspect themovable finger 470M may be driven or otherwise actuated in any suitablemanner such as with a solenoid type magnet arrangement. For example, afirst magnetic member 472A may be positioned on the base member 440B″and a second magnetic member 472B may be positioned on the actuatorportion 470MA of the movable finger 470M in an opposing relationshipwith the first magnetic member 472A. The magnetic members 472A, 472B maybe any suitable magnetic members such as, for example, neodymiummagnets. The first magnetic member 472A may be energized in any suitableway to either attract or repel the second magnetic member torespectively release or grip the sample container SC. In other aspectsthe magnetic members 472A, 472B may be positioned so that when the firstmagnetic member 472A is energized to either attract or repel the secondmagnetic member the sample container is respectively gripped orreleased. Any suitable sensor or detector 471 may be mounted to the basemember 440B″ and positioned relative to the movable finger 470M fordetecting an open (e.g. the sample container is released) and/or closed(e.g. the sample container is gripped) position of the movable finger470M. As may be realized, when the sample container SC is released bythe gripper 440A″ the sample container SC may freely fall from thegripper 440A″ substantially without resistance from the gripper 440A″.In other aspects any suitable resistance may be provided by the gripper440A″ so as to control a rate of descent of the sample container SC fromthe gripper 440A″. Any suitable connector 475 may be connected to one ormore of the sensor 471 and first magnetic member 472A and the controller170 so that suitable control signals may be provided by the controllerand sensor signal can be received by the controller for operating thegripper 440A″.

In another aspect, still referring to FIGS. 4B and 4C the gripper 440A″may be a friction gripper where the magnetic members 472A, 472B are notselectively energized. For example, the magnetic members 472A, 472B maybe arranged so as to repel each other biasing the movable finger 470M ina closed position for gripping the sample container SC. In other aspectsthe magnetic members 472A, 472B may be positioned relative to the basemember 440B″ and the movable finger 470M so that, an attractive forcebetween the magnetic members 472A, 472B biases the movable finger 470Min the closed position. The gripping portion 470MG of the movable finger470M in the biased position (without a sample container in the gripper)may be spaced from an opposing surface of the stationary finger 470S bya distance D where the distance D is smaller than a diameter, a width ora length (e.g. depending on the shape) of the sample container SC beinggripped (e.g. the gripping portion 470MG is disposed at least partlywithin the sample container passage 440P) so that as the samplecontainer SC is inserted into the gripper 440′ the gripping portion470MG is forced away from the stationary finger 470S by the samplecontainer SC and the biasing force of the magnetic members 472A, 472Beffect a compressive/friction force between the gripping portion 470MG,the stationary finger 470S and the sample container SC for gripping thesample container SC. In other aspects the biasing force may be providedin any suitable manner such as by springs or other suitable resilient orelastomeric member.

Referring now to FIG. 4D a gripper 440A′″ is shown in accordance withanother aspect of the disclosed embodiment. The gripper 440A′″ may besubstantially similar to gripper 440A however, in this aspect thegripper 440A′″ includes a moving cam member 470C that engages a samplecontainer in a manner substantially similar to that described above withrespect to the movable finger 470M. For example, movement of the cammember 470C may be effected by attractive or repelling magnetic forceswhere the magnets are energized to cause movement of the cam member 470Cin at least one of the directions 496A, 496B for opening and closing thegripper 440A′″ in a manner substantially similar to that described abovewith respect to movable finger 470M. In other aspects, the cam member470C may be biased in position within the sample container passage 440Psuch that as the sample container is moved into the sample containerpassage 440P the cam member is forced to move in the direction of arrow496B by the sample container SC where a resilient or elastomeric memberprovides a resistive force on the cam member 470C for gripping samplecontainer SC in a manner substantially similar to that described above.The cam member 470C may be coupled to the base member 440B′″ in anysuitable manner such as a pinned coupling so that the cam member pivotsabout axis RX2 in the direction of arrows 496A, 496B. As the cam member470C is moved in the direction of arrow 496A at least partly into thesample container passage 440P the cam member 470C effects gripping of asample container SC within the passage through engagement of the cammember with the sample container SC and engagement of the samplecontainer with an interior wall of the sample container passage 440P.Any suitable sensors or detectors 471 may be mounted to the base member440B′″ for sensing when the gripper 440A′″ is open or closed in a mannersubstantially similar to that described above.

In one aspect the components (e.g. base member 440B, 440B″, 440B′″,stationary finger 470S, gripping portion 470MG of movable finger 470M)of the gripper 440A, 440A′, 440A″, 440A′″ forming the sample containerpassage 440P may include a chamfer or otherwise angled surface ASrelative to an axis AX of the sample container passage 440P. The angledsurface(s) AS may be provided at one or more ends 440PE1, 440PE2 so thatat least one end 440PE1, 440PE2 of the sample container passage 440P hasa lead in for insertion of the sample container SC into the samplecontainer passage 440P. In one aspect where sample containers areinserted into the sample container passage from both ends 440PE1,440PE2, the angled surface(s) AS may be disposed at both ends 440PE1,440PE2 of the sample container passage 440P. In another aspect where thesample containers are inserted into the passage from only one end440PE1, 440PE2 the end into which the sample container SC is insertedmay include the angled surface(s) AS. The lead in formed by the angledsurfaces AS may provide guidance (e.g. guiding surfaces) for directingthe sample container into the gripper 440A, 440′, 440A″, 440A′″ andaccount for any misalignment between the sample container SC and thesample container passage 440P.

Referring now to FIG. 4E, in one aspect the gripper 441A may include abase member 441B and two movable fingers 444A, 444B coupled to the basemember 441B. In this aspect the two movable fingers 444A, 444B may forma sample container passage 440P between the fingers, however, the samplecontainer passage may not extend through the base member 441B (e.g. thesample container passage is not a through passage and only allowsinsertion of the sample container SC into the gripper 441A in onedirection 299A). In other aspects the sample container passage mayextend through the base member 441B to allow insertion of samplecontainers SC into the gripper in directions 299A, 299B. The gripper441A may include any suitable actuator(s) (such as those describedabove) connected to the movable fingers 444A, 444B for gripping (e.g.closing the gripper) and releasing (e.g. opening the gripper) samplecontainers. In one aspect the movable fingers 444A, 444B may be mountedto the base member so as to move linearly relative to the base member441B in the direction of arrow 499 towards and away from each other torespectively grip and release a sample container SC. In another aspectthe movable fingers 444A, 444B may be mounted to the base member so asto pivot relative to a predetermined axis of rotation RX2 of the basemember 441B for pivoting tips 444AT, 444BT (e.g. free ends) of themovable fingers 444A, 444B in the directions of arrows 495A, 495B,towards and away from each other to respectively grip and release asample container SC. In other aspects, the gripper 441A may have onlyone movable finger (either one of fingers 444A, 444B) which may operateas described above relative to the other finger 444A, 444B (which isstationary) for gripping and releasing a sample container SC. In thisaspect, the fop (e.g. upper) pusher member 430 may not be provided onthe at least one transfer arm portion 400A (see FIG. 4A) such that thesample containers SC may be provided to the gripper 441A by, forexample, the bottom (e.g. lower) pusher member 420 in a mannersubstantially similar to that described below and where the samplecontainers are placed into sample trays by gravity (e.g. the samplecontainer falls freely from the gripper 441A when released for placementinto a sample tray).

Referring again to FIG. 4A, the top pusher member 430 may include asample container engagement portion 430A extending therefrom towards thegripper, such as gripper 440A for exemplary purposes only. Likewise thebottom pusher member 420 may also include a sample container engagementportion 420A extending therefrom towards the gripper. Each of the samplecontainer engagement portions 430A, 420A may be substantially alignedwith the axis AX and be configured to pass at least partially throughthe sample container passage 440P to effect transfer of samplecontainers to or from the gripper as described herein. In one aspect thesample container engagement portions 430A, 420A may have a push pin orrod configuration but in other aspects the sample container engagementportions 430A, 420A may have any suitable shape and size for at least apartial insertion into the sample container passage 440P and forengagement with the sample container SC.

Referring now to FIGS. 3A, 3B, 5A and 5B, as noted above, the sampleselector module 200 may be configured to move sample containers SCbetween sample holding locations 310 within a single rack 370, 570,between multiple racks 370, 570 in a single tray 310TR and/or betweenmultiple racks 370, 570 in multiple trays 310TR. The controller 170 maybe configured to control automation of the sample selector module 200(as described herein) with a required granularity for picking andplacing sample containers SC to and from standard density trays 570 andhigh density trays 370 having any suitable spacing between samplecontainer holding locations 310. The term “standard density tray” mayrefer to trays configured to hold an array of 24 sample containers, 48sample containers or 96 sample containers. The term “high density tray”may refer to trays configured to hold an array of more than 96 samplecontainers. In one aspect the high density tray 370 may have alongitudinal (e.g. lengthwise) spacing X1 between sample holdinglocations 310 of about 8.25 mm and a lateral (e.g. widthwise) spacing X2between sample holding locations 310 of about 9.00 mm. In another aspectthe high density tray 370 may have a longitudinal spacing X1 betweensample holding locations 310 of about 8.20 mm and a lateral spacing X2between sample holding locations 310 of about 9.00 mm. In still otheraspects the spacing X1, X2 between sample holding locations may be anysuitable spacing.

As can be seen in FIGS. 5A and 5B the sample selector module 200includes a single stack ST1 (e.g. one level) of sample tray holders 300Aand a double stack ST2 (e.g. two stacked levels) of sample tray holders300B, 300B1. Each stack ST1, ST2 includes a respective axis VX1, VX2along which the respective sample tray holders 300A, 300B, 300B1 arearranged one over the other. The stacks ST1, ST2 may be spaced apartfrom one another so as to form an aisle ASL in which a respectivetransfer arm portion 400A travels. Each level in the stack may bearranged so that the level is disposed in a plane between the top pushermember 430 and the sample container holder 440 or in a plane between thesample container holder 440 and the bottom pusher member 420 so thatsample containers may be pushed between the gripper of the samplecontainer holder and a respective level of tray holders. In this aspectthe sample tray holder 300A is holding a sample tray 310TR having one ormore high density racks 370 thereon and the sample tray holders 300B,300B1 are each holding a sample tray 310TR having one or more standarddensity racks 570A, 570B thereon. The rack 570A may be a source rack(e.g. a rack from which sample containers SC are removed or picked) andracks 370, 570B may be destination racks (e.g. racks to which samplecontainers are placed).

Referring also to FIGS. 3A, 4A and 9, in this aspect the top pushermember 430 and bottom pusher member 420 are arranged to move in thedirection of arrows 299A, 299B as a unit relative to the samplecontainer holder 440 (as described above). Also in this aspect the toppusher member 430, bottom pusher member 420 and the sample containerholder 440 are arranged to rotate as a unit about axis RX (as describedabove). It is also noted that while gripper 440A is illustrated in otheraspects the gripper may be any one of the grippers 440A, 440A′, 440″,440A′″, 441A described herein (noting that the gripper 441A may onlyreceive sample containers delivered to the gripper in the direction ofarrow 299A in the aspect where the passage 440P in the gripper 441A isnot a through passage). In one aspect sample containers SC may betransferred between trays 570A, 570B stacked one above the other. Theaxis AX of the gripper may be positioned over a predetermined samplecontainer holder location 310 of the source tray in any suitable manner(FIG. 9, Block 900). For example, the transfer arm portion 400A may belinearly moved in the direction of arrow 298 and/or rotated about axisRX for substantially aligning the axis AX with the predetermined samplecontainer holder location 310 of the source tray 570A which in thisexample is disposed on a level between the top pusher member 430 and thesample container holder 440. In one aspect, the top and bottom pushermembers 430, 420 may be actuated to move in the direction of arrow 299Bto push a sample container from the predetermined sample holder locationinto the gripper 440A (FIG. 9, Block 905). It is noted that where thesource tray is on a level disposed between the bottom pusher member 420and the sample container holder 440 the top and bottom pusher members430, 420 may be actuated to move in the direction of arrow 299A to pusha sample container into the gripper 440A from the predetermined sampleholder location of the source tray. The sample container SC may betransported by the transfer arm portion 400A to substantially align theaxis AX of the gripper 440A with a predetermined sample containerholding location 310 of a destination tray 570B, 370 (FIG. 9, Block 910.In one aspect the alignment of the gripper 440A with the predeterminedsample container holding location 310 of a destination tray 570B, 370may include moving the transfer arm portion linearly in the direction ofarrow 298 and/or rotating the top pusher member 430, bottom pushermember 420 and the sample container holder 440 as a unit about axis RX(FIG. 9, Block 915). The top and bottom pusher members 430, 420 may beactuated to move in the direction of arrow 299B to push a samplecontainer from the gripper 440A into the predetermined sample holderlocation of the destination tray 370, 570B (FIG. 9, Block 920). As maybe realized, where the destination tray (which may be on the same levelas the source tray or where the source tray is also the destinationtray) is disposed on a level between the top pusher member 430 and thesample container holder 440 the top and bottom pusher members 430, 420may be actuated to move in the direction of arrow 299A to push a samplecontainer from the gripper 440A into the predetermined sample holderlocation of the destination tray.

In another aspect, when transferring a sample container SC betweensource and destination trays that are disposed one above the other, andwhere the source and destination sample container holding locations aresubstantially aligned with one another, the top and bottom pushermembers 430, 420 may be actuated so that one of the sample containerengagement portions 430A, 430B pushes the sample container from thepredetermined sample container holding location 310 of the source traythrough the sample container passage 440P (FIG. 9, Block 925) and intothe predetermined sample container holding location 310 of thedestination tray (FIG. 9, Block 920). In this aspect the samplecontainer passage 440P of the gripper guides the transfer of the samplecontainer SC between the source and destination sample container holdinglocations 310. As may be realized, the pass through transfer of samplecontainers (e.g. the transfer of the sample container completely throughthe gripper without moving the transfer arm portion 400A in thedirection of arrow 298 or about the axis RX) may be performed regardlessof whether one or more of the top pusher member 430, the bottom pushermember 420 and the sample container holder 440 are independentlyrotatable.

Still Referring to FIGS. 3A, 4A and 9 and also to FIGS. 6A and 6B, atransfer of a sample container between a source tray 570 disposed on alevel between the top pusher member 430 and the sample container holder440 and a destination tray 370 disposed on a level between the samplecontainer holder 440 and the bottom pusher member 420 will be described.In this aspect at least the bottom pusher member 420 may beindependently rotatable about axis RX relative to the sample containergripper 440. In this aspect the axis AX of the gripper may be positionedover a predetermined sample container holder location 310 of the sourcetray in any suitable manner (FIG. 9, Block 900). For example, thetransfer arm portion 400A may be linearly moved in the direction ofarrow 298 and/or the bottom pusher member 420, the top pusher member 430and the sample container holder 440 (e.g. rotation of the bottom pushermember 420 is controlled independently from rotation of the upper pushermember 430 and sample container holder 440) are rotated about axis RXfor substantially aligning the axis AX with the predetermined samplecontainer holder location 310 of the source tray 570 which in thisexample is disposed on a level between the fop pusher member 430 and thesample container holder 440. In one aspect, at least the top pushermember 430 may be actuated to move in the direction of arrow 299B topush a sample container from the predetermined sample holder locationinto the gripper 440A (FIG. 9, Block 905). In one aspect the top andbottom pusher members 430, 420 may move in the direction of arrows 299A,229B as a unit while in other aspects the top and bottom pusher members430, 420 may be independently movable in the directions of arrows 299A,299B. It is noted that where the source tray is on a level disposedbetween the bottom pusher member 420 and the sample container holder 440at least the bottom pusher member 420 may be actuated to move in thedirection of arrow 299A to push a sample container into the gripper 440Afrom the predetermined sample holder location of the source tray. Thesample container SC may be transported by the transfer arm portion 400Ato substantially align the axis AX of the gripper 440A with apredetermined sample container holding location 310 of a destinationtray 570B, 370 (FIG. 9, Block 910). ID one aspect the alignment of thegripper 440A with the predetermined sample container holding location310 of a destination tray 370 may include moving the transfer armportion 400A linearly in the direction of arrow 298 and/or rotating thesample container holder 440 and the top pusher member 430 as a unitabout axis RX (FIG. 9, Block 915). In one aspect the bottom pushermember 420 may also be rotated, albeit independently from the unitaryrotation of the top pusher member 430 and the sample container holder440. Here the top pusher member 430 may be actuated to move in thedirection of arrow 299B to push a sample container from the gripper 440Ainto the predetermined sample holder location of the destination tray370 (FIG. 9, Block 920). As may be realized, where the destination tray(which may be on the same level as the source tray or where the sourcetray is also the destination tray) is disposed on a level between thetop pusher member 430 and the sample container holder 440 the bottompusher member 420 may be actuated to move in the direction of arrow 299Ato push a sample container from the gripper 440A into the predeterminedsample holder location of the destination tray.

Referring to FIGS. 3A, 4A and 9 and also to FIGS. 7A and 7B, a transferof a sample container between a source tray 370 disposed on a levelbetween the bottom pusher member 420 and the sample container holder 440and a destination tray 570 disposed on a level between the samplecontainer holder 440 and the bottom pusher member 420 will be described.In this aspect both the top pusher member 430 and the bottom pushermember 420 may be independently rotatable about axis RX relative to thesample container gripper 440. In this aspect the axis AX of the grippermay be positioned over a predetermined sample container holder location310 of the source tray in any suitable manner (FIG. 9, Block 900). Forexample, the transfer arm portion 400A may be linearly moved in thedirection of arrow 298 and/or the sample container holder 440 may berotated about axis RX for substantially aligning the axis AX with thepredetermined sample container holder location 310 of the source tray370. One or more of the top pusher member 430 and the bottom pushermember 420 (e.g. depending on a level of the source tray) may beindependently rotated so that the respective sample container engagementportion 430A, 420A is substantially aligned with the axis AX and thepredetermined sample holding location 310 of the source tray 370. Inthis example, the source tray 370 is disposed on a level between thebottom pusher member 420 and the sample container holder 440 so thebottom pusher member 420 is independently rotated about axis RX toremove the sample container SC from the source tray 370. In one aspect,at least the bottom pusher member 420 may be actuated to move in thedirection of arrow 299A to push a sample container SC from thepredetermined sample holder location into the gripper 440A (FIG. 9,Block 905). In one aspect the top and bottom pusher members 430, 420 maymove in the direction of arrows 299A, 229B as a unit while in otheraspects the top and bottom pusher members 430, 420 may be independentlymovable in the directions of arrows 299A, 299B. If is noted that wherethe source tray is on a level disposed between the top pusher member 430and the sample container holder 440 at least the top pusher member 430may rotated and actuated to move in the direction of arrow 299B to pusha sample container into the gripper 440A from the predetermined sampleholder location of the source tray. The sample container SC may betransported by the transfer arm portion 400A to substantially align theaxis AX of the gripper 440A with a predetermined sample containerholding location 310 of a destination tray 570B, 370 (FIG. 9, Block910). In one aspect the alignment of the gripper 440A with thepredetermined sample container holding location 310 of the destinationtray 570 may include moving the transfer arm portion 400A linearly inthe direction of arrow 298 and/or rotating the sample container holder440 about axis RX (FIG. 9, Block 930). Here one or more of the toppusher member 430 and the bottom pusher member 420 may also beindependently rotated so that the respective sample container engagementportion 430A, 420A is substantially aligned with the axis AX and thepredetermined sample holding location 310 of the destination tray 570(FIG. 9, Block 935). Here at least the top pusher member 430 may beactuated to move in the direction of arrow 299B to push a samplecontainer from the gripper 440A into the predetermined sample holderlocation of the destination tray 570 (FIG. 9, Block 920). As may berealized, where the destination tray (which may be on the same level asthe source tray or where the source fray is also the destination tray)is disposed on a level between the top pusher member 430 and the samplecontainer holder 440 the bottom pusher member 420 may be actuated tomove in the direction of arrow 299A to push a sample container from thegripper 440A into the predetermined sample holder location of thedestination tray.

The exemplary sample container transfer described with respect to FIGS.5A-7B involves sample container transport between high density trays 370and standard density trays 570 and between multiple standard densitytrays. Referring now to FIGS. 8A and 8B sample container transfer mayalso be provided between multiple high density trays 370A, 370B in amanner substantially described above with respect to FIGS. 5A-7B. It isnoted that the example illustrated in FIGS. 8A and 8B is similar to thatillustrated in FIGS. 7A and 7B where the top and bottom pusher members430, 420 are each independently rotatable relative to the samplecontainer holder 440 such that sample container transfer is performed ina manner substantially similar to that described above with respect toFIGS. 7A and 7B.

It should be understood that while transfer of sample containers intothe high density trays 370 as described herein are into trays 370disposed on a level between the sample container holder 440 and thebottom pusher member, in other aspects transfer of sample containersinto a high density tray 370 disposed on a level between the top pushermember 430 and the sample container holder 440 may occur in a mannersubstantially similar to that described above with respect to thestandard density trays 570A. It should also be understood that where twosource or two destination trays are disposed one above the other one ormore of the bottom pusher member 420 and top pusher member 730 may beindependently movable in the direction of arrows 299A, 299B relative tothe other one of top pusher member 430 and bottom pusher member 420 aswell as the sample container holder 440 to prevent unwanted insertion ofa respective sample container engagement portion 430A, 420A into anoccupied sample container holding location 310.

Referring now to FIGS. 10A and 10B in one aspect, the upper pusher arm430 and the lower pusher arm 420 could be used to clamp a samplecontainer SC between them for transfer of the sample container SC to andfrom the gripper 440A. For example, where the rack (such as rack 570shown in FIGS. 10A and 10B or any other suitable rack such as rack 370)is disposed between the sample container holder 440 and the lower pusherarm 420 as illustrated in FIG. 10A, the upper pusher arm 430 may bemoved in the direction of arrow 299B towards a top surface of the samplecontainer SC such that the sample container engagement portion 430Aextends through the gripper 440A to substantially contact the topsurface of the sample container SC. The lower pusher arm 420 may bemoved in the direction of arrow 299A towards the sample container sothat the sample container engagement portion 420A substantially contactsa bottom surface of the sample container SC such that the samplecontainer is clamped between the sample container engagement portions430A, 420A.

Similarly, where the rack (such as rack 570 shown in FIGS. 10A and 10Bor any other suitable rack such as rack 370) is disposed between thesample container holder 440 and the upper pusher arm 430 as illustratedin FIG. 10B, the lower pusher arm 420 may be moved in the direction ofarrow 299A towards a bottom surface of the sample container SC such thatthe sample container engagement portion 420A extends through the gripper440A to substantially contact the bottom surface of the sample containerSC. The upper pusher arm 430 may be moved in the direction of arrow 299Btowards the sample container so that the sample container engagementportion 430A substantially contacts the bottom surface of the samplecontainer SC such that the sample container is clamped between thesample container engagement portions 430A, 420A.

As may be realized, after the container is clamped between the samplecontainer engagement portions 430A, 420A, the sample container SC can bemoved to the gripper 440A via simultaneous movement of the upper andlower pusher arms 420, 430 in one of the directions 299A, 299B dependingon, for example, a location of the tray 570 relative to the gripper.Transfer of the sample container SC in this manner may provide higheralignment reliability by holding the sample container SC to itslongitudinal axis. Also referring to FIG. 10C, the ends 1000A, 1000B ofthe sample container engagement portions 430A, 420A could be adapted tocradle the ends of the sample container and/or, referring to FIG. 10D,the sample container could have features 1001A, 1001B configured toregister with the ends 1000A, 1000B of the sample container engagementportions 430A, 420A. In another aspect, the upper and lower pusher arms430, 420 may clamp the sample container SC during rotation about axis RXsuch that one of the upper and lower pusher arms 430, 420 is moved inthe direction of arrow 299A, 299B to clear the tray 570 and then move inthe direction of arrow 299A, 299B to re-engage the sample container SCduring rotation about axis RX.

In accordance with one or more aspects of the disclosed embodiment anapparatus includes a frame configured to hold sample holders in an arrayof sample holder locations, each sample holder being disposed in thearray with a longitudinal axis of the sample holder extending outward ofan array plane; a drive section connected to the frame; at least onetransfer arm rotatably connected to the drive section so that eachtransfer arm rotates about a respective rotation axis orientedsubstantially parallel with the longitudinal axis of the sample holder,each transfer arm including a sample holder gripper configured to grip asample holder; and at least one push member movably connected to thedrive section, the at least one push member being distinct from thesample holder gripper and configured for linear movement along thelongitudinal axis of the sample holder relative to a respective transferarm and sample holder gripper, the at least one push member beingconfigured so that engagement with at least a bottom or top surface ofthe sample holder effects longitudinal translation of the sample holderfor one or more of capture and release of the sample holder by therespective transfer arm in the longitudinal direction.

In accordance with one or more aspects of the disclosed embodiment thesample holder gripper is configured to engage and grip the sample holderthrough a friction grip.

In accordance with one or more aspects of the disclosed embodiment thesample holder gripper includes a clamp member configured to activelyengage and grip the sample holder through a clamp actuation.

In accordance with one or more aspects of the disclosed embodiment theat least one push member comprises another push member movably connectedto the drive section, the other push member being distinct from thesample holder gripper and configured for linear movement along thelongitudinal axis of the sample holder relative to the respectivetransfer arm and sample holder gripper, the other push member beingconfigured so that engagement with at least a bottom or top surface ofthe sample holder effects longitudinal translation of the sample holderfor one or more of capture and release of the sample holder by therespective transfer arm in the longitudinal direction.

In accordance with one or more aspects of the disclosed embodiment theat least one push member and the other push member are configured toclamp the sample holder between the at least one push member and theother push member.

In accordance with one or more aspects of the disclosed embodiment therespective transfer arm and the other push member are arranged so as tobe located on opposite sides of a sample tray disposed within theapparatus where the sample tray being configured to hold at least onesample container.

In accordance with one or more aspects of the disclosed embodiment therespective transfer arm and the other push member are arranged so as tobe located on a common side of a sample tray disposed within theapparatus where the sample tray being configured to hold at least onesample container.

In accordance with one or more aspects of the disclosed embodiment oneor more of the at least one push member and the other push member areindependently rotatable about the respective rotation axis relative toat least one of the respective transfer arm, sample holder gripper andeach other.

In accordance with one or more aspects of the disclosed embodiment oneor more of the at least one push member and the other push member rotatewith the respective transfer arm as a unit about the respective rotationaxis.

In accordance with one or more aspects of the disclosed embodiment theat least one push member is independently rotatable about the respectiverotation axis relative to the respective transfer arm and sample holdergripper.

In accordance with one or more aspects of the disclosed embodiment theat least one push member rotates with the respective transfer arm as aunit about the respective rotation axis.

In accordance with one or more aspects of the disclosed embodiment thesample holder gripper of the respective transfer arm and the at leastone push member are arranged so as to be located on opposite sides of asample tray disposed within the apparatus where the sample tray beingconfigured to hold at least one sample container.

In accordance with one or more aspects of the disclosed embodiment thesample holder gripper of the respective transfer arm and the at leastone push member are arranged so as to be located on a common side of asample fray disposed within the apparatus where the sample tray beingconfigured to hold at least one sample container.

In accordance with one or more aspects of the disclosed embodiment theapparatus further includes an isolation member that divides the frameinto isolated environments so that the drive section is isolated from anenvironment in which the at least one transfer arm and respective sampleholder gripper operate.

In accordance with one or more aspects of the disclosed embodiment theisolation member includes at least one sealed penetration through whichthe at least one transfer arm extends.

In accordance with one or more aspects of the disclosed embodiment theat least, one transfer arm linearly moves in the array plane along alinear travel axis and the sealed penetration is configured to move withthe at least one transfer arm along the linear travel axis.

In accordance with one or more aspects of the disclosed embodiment thesealed penetration comprises a slot through which the at least onetransfer arm moves.

In accordance with one or more aspects of the disclosed embodiment thedrive section includes a first drive for at least rotating at least oneof the sample holder gripper and the at least one push member about therespective rotation axis, and a second drive for linearly translatingthe respective transfer arm and the at least one push member in adirection transverse to the respective rotation axis.

In accordance with one or more aspects of the disclosed embodiment theapparatus further includes at least one sample tray holder configured sothat one or more sample trays are slid into a respective sample trayholding area, wherein the at least one transfer arm is configured tomove sample holders between sample holding locations of the one or moresample trays.

In accordance with one or more aspects of the disclosed embodiment theat least one sample tray holder includes a retaining mechanism forholding the one or more sample trays in the respective sample trayholding area.

In accordance with one or more aspects of the disclosed embodiment theat least one transfer arm comprises two transfer arms disposed onopposite sides of a sample tray holding area within the frame.

In accordance with one or more aspects of the disclosed embodiment theframe defines a chamber arranged at least partly inside of a cold store.

In accordance with one or more aspects of the disclosed embodiment theframe is configured to mate with a closable opening in a wall of thecold store.

In accordance with one or more aspects of the disclosed embodiment theframe defines at least one closable opening within the cold storethrough which sample holders are inserted and removed from the frame,and includes a sliding closure magnetically sealed to the chamber forsealing a respective closable opening.

In accordance with one or more aspects of the disclosed embodiment theframe further defines a closable access opening, distinct from the atleast one closable opening, configured to provide access to an interiorof the frame.

In accordance with one or more aspects of the disclosed embodiment theclosable access opening is disposed external to the cold store.

In accordance with one or more aspects of the disclosed embodiment thechamber is a portable chamber disposed on a transfer shuttle of the coldstore.

In accordance with one or more aspects of the disclosed embodiment thesample holder gripper is an interchangeable gripper configured to beremoved from and attached to the at least one transfer arm.

In accordance with one or more aspects of the disclosed embodiment anapparatus includes a frame; a sample tray holding area including atleast a first and second tray holder disposed in a tray holder plane,each tray holder being configured for a sliding insertion of one or moresample trays into the tray holder and for holding the sample trays sothat longitudinal axes of sample holders within the frays extend outwardof the tray holder plane; a drive section connected to the frame; and atleast one transfer arm connected to the drive section and being disposedin an aisle between the first and second tray holder, the at least onetransfer arm including a rotation axis oriented substantially parallelwith the longitudinal axes of the sample holders, a sample gripper, anda push member, the push member is configured for linear movementrelative to the sample gripper, where the sample gripper and push memberare arranged so as to rotate as a unit about the rotation axis.

In accordance with one or more aspects of the disclosed embodiment thepush member is configured for longitudinal linear movement relative tothe sample gripper and engagement with one or more of at least a topfacing surface and at least a bottom facing surface of a sample holdereffecting longitudinal translation of the sample holder between a sampletray and the sample gripper for one or more of capture and release ofthe sample holder by the sample gripper in the longitudinal direction.

In accordance with one or more aspects of the disclosed embodiment thepush member comprises a first push member, the sample gripper and thefirst push member are arranged so as to be located on opposite sides ofthe sample tray disposed within the apparatus, the first push memberbeing configured for at least partial insertion through a sample holdinglocation of the sample tray, and engagement with a bottom facing surfaceor a top facing surface of the sample holder to transport the sampleholder to the sample gripper.

In accordance with one or more aspects of the disclosed embodiment thepush actuator comprises a second push member in opposing relation to thefirst push member, the sample gripper and the second push member arearranged so as to be located on a common side of the sample tray, thesecond push member being configured for at least partial insertionthrough the sample gripper, and engagement with the bottom facingsurface or top facing surface of the sample holder to transfer thesample holder to the sample tray.

In accordance with one or more aspects of the disclosed embodiment thefirst push member and the second push member are configured to clamp thesample holder between the first push member and the second push member.

In accordance with one or more aspects of the disclosed embodiment thepush actuator comprises a second push member, the sample gripper and thesecond push member are arranged so as to be located on opposite sides ofanother sample tray, the second push member being configured for atleast partial insertion through the sample gripper, and engagement withanother of the bottom facing surface or top facing surface of the sampleholder to transfer the sample holder to the sample gripper.

In accordance with one or more aspects of the disclosed embodiment thesample gripper forms a sample holder passage configured to guide passageof the sample holder between the sample tray and the another sample trayand at least one of the first push member and second push member isconfigured to transfer the sample holder through the sample holderpassage between the sample tray and the another sample tray.

In accordance with one or more aspects of the disclosed embodiment theapparatus further includes an isolation member that divides the frameinto isolated environments so that the drive section is isolated from anenvironment in which the transfer arm operates.

In accordance with one or more aspects of the disclosed embodiment theisolation member includes a dynamically sealed penetration through whichthe at least one transfer arm member extends.

In accordance with one or more aspects of the disclosed embodiment thesealed penetration comprises a slot through which the at least onetransfer arm moves.

In accordance with one or more aspects of the disclosed embodiment theframe defines a chamber arranged at least partly inside of a cold store.

In accordance with one or more aspects of the disclosed embodiment theframe is configured to mate with a closable opening in a wall of thecold store.

In accordance with one or more aspects of the disclosed embodiment theframe defines at least one closable opening within the cold storethrough which sample holders are inserted and removed from the frame,and includes a sliding closure magnetically sealed to the chamber forsealing a respective closable opening.

In accordance with one or more aspects of the disclosed embodiment theframe further defines a closable access opening, distinct from the atleast one closable opening, configured to provide access to an interiorof the frame.

In accordance with one or more aspects of the disclosed embodiment theclosable access opening is disposed external to the cold store.

In accordance with one or more aspects of the disclosed embodiment thechamber is a portable chamber disposed on a transfer shuttle of the coldstore.

In accordance with one or more aspects of the disclosed embodiment theat least one transfer arm includes a coaxial drive shaft assembly, thesample gripper being coupled to one drive shaft of the coaxial driveshaft assembly and the push member being coupled to another drive shaftof the coaxial drive shaft assembly.

In accordance with one or more aspects of the disclosed embodiment anapparatus includes a frame configured to hold an array of sample holdersin sample trays; a drive section connected to the frame; a transfer armat least rotatably connected to the drive section, the transfer armhaving an axis of rotation and including a sample holder gripper, atleast one pusher member mounted to the transfer arm so as to movelinearly relative to the sample holder gripper and being configured tolinearly transfer a sample holder between the sample trays and thesample holder gripper; and a controller connected to the drive sectionand being configured to effect, through movement of the transfer arm andthe at least one pusher member, transfer of sample holders betweensample trays having different sample holder holding capacities.

In accordance with one or more aspects of the disclosed embodiment thecontroller is configured to effect transfer of sample holders betweensample trays having the same sample holder holding capacities.

In accordance with one or more aspects of the disclosed embodiment thearray of sample holders is held in at least one sample holding plane andthe sample holders have a longitudinal axis extending outwards of thesample holding plane, and the transfer arm has an axis of rotationsubstantially parallel with the longitudinal axis, where the sampleholder gripper and the at least one pusher member rotate as a unit aboutthe axis of rotation.

In accordance with one or more aspects of the disclosed embodiment thearray of sample holders is held in at least one sample holding plane andthe sample holders have a longitudinal axis extending outwards of thesample holding plane, and the transfer arm has an axis of rotationsubstantially parallel with the longitudinal axis, where the sampleholder gripper and at least one of the at least one pusher member rotateindependently about the axis of rotation.

In accordance with one or more aspects of the disclosed embodiment theat least one sample holding plane includes two stacked sample holdingplanes where the sample holder gripper is disposed between the twostacked sample holding planes, and the at least one pusher member isdisposed on an opposite side of a respective one of the two stackedsample holding planes relative to the sample holder gripper.

In accordance with one or more aspects of the disclosed embodiment thesample holder gripper includes a sample holder passage configured toguide sample holder transfer from a sample tray disposed in a first oneof the two stacked sample holding planes to sample tray in a second oneof the two sample holding planes.

In accordance with one or more aspects of the disclosed embodiment theframe defines a housing having at least one chamber, the housing beingconfigured for placement at least partially within a cold store.

In accordance with one or more aspects of the disclosed embodiment amethod for transferring sample holders in a cold storage environmentwhere the sample holders are held in an array of sample holder locationsand being disposed in the array with a longitudinal axis of the sampleholder extending outward of an array plane is provided. The methodincludes aligning a sample holder gripper and at least one push memberwith a predetermined sample holder in the array by at least rotating thesample holder gripper and the at least one push member about a commonaxis of rotation that is substantially parallel with the longitudinalaxis, where the at least one push member is distinct from the sampleholder gripper; and transferring the predetermined sample holder betweenthe array and the sample holder gripper, for one or more of capture andrelease of the sample holder by the sample holder gripper in thelongitudinal direction, by linearly moving the at least one push memberrelative to the sample holder gripper in the longitudinal direction forengaging at least a bottom or top surface of the sample holder andeffecting longitudinal translation of the sample holder.

In accordance with one or more aspects of the disclosed embodimentaligning the sample holder gripper and the at least one push member withthe predetermined sample holder includes rotating the sample holdergripper and the at least one push member as a unit about the common axisof rotation.

In accordance with one or more aspects of the disclosed embodimentaligning the sample holder gripper and the at least one push member withthe predetermined sample holder includes independently rotating thesample holder gripper and one or more of the at least one push memberabout the common axis of rotation.

In accordance with one or more aspects of the disclosed embodimentaligning the sample holder gripper and the at least one push member withthe predetermined sample holder includes linearly translating the sampleholder gripper and the at least one push member as a unit in a directiontransverse to the longitudinal axis.

In accordance with one or more aspects of the disclosed embodiment thearray of sample holder locations are arranged in arrays in stackedlevels where each level has a respective array plane, the method furtherincludes transferring the predetermined sample holder from a sampleholding location disposed in one stacked level to a sample holdinglocation in another stacked level through a pass-through guide passageof the sample holder gripper.

In accordance with one or more aspects of the disclosed embodiment theat least one push member includes a first push member and a second pushmember, the method further includes clamping the predetermined sampleholder between the first push member and the second push member fortransferring the predetermined sample holder to the sample holdergripper.

It should be understood that the foregoing description is onlyillustrative of the aspects of the disclosed embodiment. Variousalternatives and modifications can be devised by those skilled in theart without departing from the aspects of the disclosed embodiment.Accordingly, the aspects of the disclosed embodiment are intended toembrace all such alternatives, modifications and variances that fallwithin the scope of the appended claims. Further, the mere fact thatdifferent features are recited in mutually different dependent orindependent claims does not indicate that a combination of thesefeatures cannot be advantageously used, such a combination remainingwithin the scope of the aspects of the invention.

What is claimed is:
 1. An apparatus comprising: a frame; a sample trayholding area including at least a first and a second tray holderdisposed in a tray holder plane and separated from each other by anaisle between the first and the second tray holder, each tray holderbeing configured for a sliding insertion of one or more sample traysinto the tray holder and for holding the sample trays so thatlongitudinal axes of sample holders within the trays extend outward ofthe tray holder plane; a drive section connected to the frame; and atleast one transfer arm connected to the drive section and being disposedin the aisle between and separating the first and the second tray holderso as to extend through the aisle between the first and second trayholders, the at least one transfer arm including a rotation axisoriented substantially parallel with the longitudinal axes of the sampleholders, a sample gripper, and a push member, the push member isconfigured for linear movement relative to the sample gripper, where thesample gripper and push member are arranged so that at least one of thesample gripper and push member rotates about the rotation axis.
 2. Theapparatus of claim 1, wherein the sample gripper and the push member arearranged so as to rotate about the rotational axis.
 3. The apparatus ofclaim 1, wherein the sample gripper and the push member are arranged soas to rotate as a unit about the rotational axis.
 4. An apparatuscomprising: a frame; a sample tray holding area including at least afirst and a second tray holder disposed in a tray holder plane andseparated from each other by an aisle between the first and the secondtray holder, each tray holder being configured for a sliding insertionof one or more sample trays into the tray holder and for holding thesample trays so that longitudinal axes of sample holders within thetrays extend outward of the tray holder plane; a drive section connectedto the frame; at least one transfer arm connected to the drive sectionand being disposed in the aisle between and separating the first and thesecond tray holder so as to extend through the aisle between the firstand second tray holders, the at least one transfer arm including arotation axis oriented substantially parallel with the longitudinal axesof the sample holders, and a sample gripper arranged so as to rotateabout the rotational axis; and an isolation member that divides theframe into isolated environments so that the drive section is isolatedfrom an environment in which the at least one transfer arm operates. 5.The apparatus of claim 4, wherein the at least one transfer arm includesa coaxial drive shaft assembly, the sample gripper being coupled to onedrive shaft of the coaxial drive shaft assembly and the push memberbeing coupled to another drive shaft of the coaxial drive shaftassembly.
 6. The apparatus of claim 4, wherein the isolation memberincludes a dynamically sealed penetration through which the at least onetransfer arm extends.
 7. The apparatus of claim 6, wherein thedynamically sealed penetration comprises a slot through which the atleast one transfer arm moves.
 8. The apparatus of claim 4, wherein theat least one transfer arm further includes a push member, the pushmember being configured for linear movement relative to the samplegripper, and where the sample gripper and push member are arranged sothat at least one of the sample gripper and the push member rotatesabout the rotational axis.
 9. The apparatus of claim 8, wherein thesample gripper and the push member are arranged so as to rotate aboutthe rotational axis.
 10. The apparatus of claim 8, wherein the samplegripper and the push member are arranged so as to rotate as a unit aboutthe rotational axis.
 11. The apparatus of claim 8, wherein the pushmember is configured for longitudinal linear movement relative to thesample gripper and engagement with one or more of at least a top facingsurface and at least a bottom facing surface of a sample holdereffecting longitudinal translation of the sample holder between a sampletray and the sample gripper for one or more of capture and release ofthe sample holder by the sample gripper in a longitudinal direction. 12.The apparatus of claim 8, wherein the push member comprises a first pushmember, the sample gripper and the first push member are arranged so asto be located on opposite sides of the sample tray disposed within theapparatus, the first push member being configured for at least partialinsertion through a sample holding location of the sample tray, andengagement with a bottom facing surface or a top facing surface of thesample holder to transport the sample holder to the sample gripper. 13.The apparatus of claim 12, wherein the push member comprises a secondpush member in opposing relation to the first push member, the samplegripper and the second push member are arranged so as to be located on acommon side of the sample tray, the second push member being configuredfor at least partial insertion through the sample gripper, andengagement with the bottom facing surface or top facing surface of thesample holder to transfer the sample holder to the sample tray.
 14. Theapparatus of claim 12, wherein the push member comprises a second pushmember, the sample gripper and the second push member are arranged so asto be located on opposite sides of another sample tray, the second pushmember being configured for at least partial insertion through thesample gripper, and engagement with another of the bottom facing surfaceor top facing surface of the sample holder to transfer the sample holderto the sample gripper.
 15. The apparatus of claim 14, wherein the samplegripper forms a sample holder passage configured to guide passage of thesample holder between the sample tray and the another sample tray and atleast one of the first push member and the second push member isconfigured to transfer the sample holder through the sample holderpassage between the sample tray and the another sample tray.
 16. Theapparatus of claim 4, wherein the frame defines a chamber arranged atleast partly inside of a cold store.
 17. The apparatus of claim 16,wherein the frame is configured to mate with a closable opening in awall of the cold store.
 18. The apparatus of claim 16, wherein thechamber is a portable chamber disposed on a transfer shuttle of the coldstore.
 19. The apparatus of claim 16, wherein the frame defines at leastone closable opening within the cold store through which sample holdersare inserted and removed from the frame, and includes a sliding closuremagnetically sealed to the chamber for sealing a respective closableopening.
 20. The apparatus of claim 19, wherein the frame furtherdefines a closable access opening, distinct from the at least oneclosable opening, configured to provide access to an interior of theframe.
 21. The apparatus of claim 20, wherein the closable accessopening is disposed external to the cold store.